A compressor system includes a lead compressor operable to produce a flow of compressed fluid at a first output and a lag compressor operable to produce a flow of compressed fluid at a second output. The sum of the first output and the second output defines a system output. A lead variable speed motor is operable to drive the lead compressor at a first compressor speed to vary the first output and a lag variable speed motor is operable to drive the lag compressor at a second compressor speed to vary the second output. A sensor is operable to measure a system load, and a lead motor drive is operable to control the speed of the lead variable speed motor and to set a desired operating state of the lag variable speed motor in response to a comparison of the system load and the system output.
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20. A method of operating multiple compressors in a compressor system, the method comprising:
operating a lead compressor between a minimum output and a maximum output to define a lead compressor output;
operating a lag compressor between a minimum output and a maximum output to define a lag compressor output;
combining the lead compressor output and the lag compressor output to define a system output;
measuring a system load with a sensor;
comparing the system load and the system output;
setting the speed of the lead compressor using a lead variable speed drive;
determining a desired operating state for the lag compressor using the lead variable speed drive and a comparison of the system load and the system output;
providing to a lag variable speed drive the desired operating state; and
operating the lag compressor in the desired operating state in response to receipt of the desired operating state.
6. A compressor system comprising:
a lead compressor operable to produce a flow of compressed fluid at a first output;
a lag compressor operable to produce a flow of compressed fluid at a second output, the sum of the first output and the second output defining a system output;
a lead variable speed motor operable to drive the lead compressor at a first compressor speed to vary the first output;
a lag variable speed motor operable to drive the lag compressor at a second compressor speed to vary the second output;
a sensor operable to measure a system load; and
a lead motor drive operable to control the speed of the lead variable speed motor and to set a desired operating state of the lag variable speed motor in response to a comparison of the system load and the system output, wherein the lead motor drive switches the lead compressor between a first region of operation and a second region of operation in response to a measured system load equal to a maximum output of the lead compressor.
1. A compressor system comprising:
a lead compressor operable to produce a flow of compressed fluid at a first output;
a lag compressor operable to produce a flow of compressed fluid at a second output, the sum of the first output and the second output defining a system output;
a lead variable speed motor operable to drive the lead compressor at a first compressor speed to vary the first output;
a lag variable speed motor operable to drive the lag compressor at a second compressor speed to vary the second output;
a sensor operable to measure a system load;
a lead motor drive operable to control the speed of the lead variable speed motor and to set a desired operating state of the lag variable speed motor in response to a comparison of the system load and the system output; and
a lag motor drive operable to control the speed of the lag variable speed motor, wherein the lag motor drive communicates with the lead motor drive to receive the desired operating state from the lead motor drive.
9. A compressor system comprising:
a lead compressor operable to produce a flow of compressed fluid at a first output;
a lag compressor operable to produce a flow of compressed fluid at a second output, the sum of the first output and the second output defining a system output;
a lead variable speed motor operable to drive the lead compressor at a first compressor speed to vary the first output;
a lag variable speed motor operable to drive the lag compressor at a second compressor speed to vary the second output;
a sensor operable to measure a system load;
a lag motor drive operable to control the speed of the lag variable speed motor; and
a lead motor drive operable in a first region of operation to drive the lead variable speed motor at a speed that maintains the first output between a first minimum and a first maximum, and to provide a desired operating state to the lag motor drive to maintain the second output between a second minimum and a second maximum, the lead motor drive also operable in a second region of operation to drive the lead variable speed motor at a speed that maintains the first output between a third minimum and a third maximum, the third minimum being different than the first minimum.
8. A compressor system comprising:
a lead compressor operable to produce a flow of compressed fluid at a first output;
a lag compressor operable to produce a flow of compressed fluid at a second output, the sum of the first output and the second output defining a system output;
a lead variable speed motor operable to drive the lead compressor at a first compressor speed to vary the first output;
a lag variable speed motor operable to drive the lag compressor at a second compressor speed to vary the second output;
a sensor operable to measure a system load; and
a lead motor drive operable to control the speed of the lead variable speed motor and to set a desired operating state of the lag variable speed motor in response to a compression of the system load and the system output, wherein the lag compressor is one of a plurality of lag compressors, the plurality of lag compressors operable to produce a plurality of second outputs, the sum of the first output and the plurality of second outputs defining the system output;
wherein the lag variable speed motor is one of a plurality of lag variable speed motors, the lag variable speed motors operable to control the speeds of the plurality of lag compressors; and
wherein the lead motor drive provides a desired operating state to each of the plurality of lag variable speed motors in response to the comparison of the system load and the system output.
2. The compressor system of
3. The compressor system of
5. The compressor system of
7. The compressor system of
10. The compressor system of
11. The compressor system of
12. The compressor system of
13. The compressor system of
14. The compressor system of
15. The compressor system of
16. The compressor system of
17. The compressor system of
19. The compressor system of
21. The method of
22. The method of
resetting the minimum output of the lead compressor to a second minimum output that is greater than the minimum output; and
initiating operation of the lag compressor.
23. The method of
resetting the minimum output to the first minimum; and
terminating operation of the lag compressor.
24. The method of
25. The method of
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The present invention relates to compressor systems, and more particularly to a compressor system utilizing a lead compressor and at least one lag compressor.
In some applications, it is more efficient to use two or more smaller compressors rather than one large compressor. Generally, a system controller controls the output of the various compressors in the system by controlling the output of each compressor.
One construction of the invention provides a compressor system that includes a lead compressor operable to produce a flow of compressed fluid at a first output and a lag compressor operable to produce a flow of compressed fluid at a second output. The sum of the first output and the second output defines a system output. A lead variable speed motor is operable to drive the lead compressor at a first compressor speed to vary the first output and a lag variable speed motor is operable to drive the lag compressor at a second compressor speed to vary the second output. A sensor is operable to measure a system load, and a lead motor drive is operable to control the speed of the lead variable speed motor and to set a desired operating state of the lag variable speed motor in response to a comparison of the system load and the system output.
In another construction, the invention provides a compressor system that includes a lead compressor operable to produce a flow of compressed fluid at a first output and a lag compressor operable to produce a flow of compressed fluid at a second output. The sum of the first output and the second output defines a system output. A lead variable speed motor is operable to drive the lead compressor at a first compressor speed to vary the first output, and a lag variable speed motor is operable to drive the lag compressor at a second compressor speed to vary the second output. A sensor is operable to measure a system load. A lag motor drive is operable to control the speed of the lag variable speed motor. A lead motor drive is operable in a first region of operation to drive the lead variable speed motor at a speed that maintains the first output between a first minimum and a first maximum and to provide a desired operating state to the lag motor drive to maintain the second output between a second minimum and a second maximum. The lead motor drive is also operable in a second region of operation to drive the lead variable speed motor at a speed that maintains the first output between a third minimum and a third maximum, the third minimum being different than the first minimum.
In yet another construction, the invention provides a method of operating multiple compressors in a compressor system. The method includes operating a lead compressor between a minimum output and a maximum output to define a lead compressor output, operating a lag compressor between a minimum output and a maximum output to define a lag compressor output, combining the lead compressor output and the lag compressor output to define a system output, measuring a system load with a sensor, comparing the system load and the system output, setting the speed of the lead compressor using a lead variable speed drive, determining a desired operating state for the lag compressor using the lead variable speed drive and a comparison of the system load and the system output, providing to a lag variable speed drive the desired operating state, and operating the lag compressor in the desired operating state in response to receipt of the desired operating state.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
The output of a compressor may be described in different ways. For example, the output may be described as a percentage or percent output. The percent output of a compressor is simply the flow rate of compressed fluid exiting the compressor divided by the maximum flow rate of compressed fluid that the compressor is capable of outputting, converted to a percentage. The percent output of the compressor will be referred to herein as the output. The output of a compressor may also be described in terms of its turn down. The turn down capability of a compressor indicates the range at which the compressor can operate. For example, if a compressor has a turn down of 70%, then the compressor is able to produce an output between 30% and 100%. If a compressor is turned down 70%, then the compressor is operating at 30%, or with 30% output.
The lead compressor 18 is a rotary screw compressor and may be oil-flooded or oil-less. The lead compressor 18 contains an inlet 30 and an outlet 34. The lead compressor 18 draws in a working fluid, such as air, through the inlet 30 and discharges or outputs the working fluid as a flow of compressed fluid through the outlet 34. The lead compressor 18 may compress other working fluids such as nitrogen, refrigerant, ammonia, etc.
The lead variable speed motor 22 preferably includes a variable-frequency motor that drives a motor shaft 38 coupled to the lead compressor 18 to drive the lead compressor 18. The lead variable speed motor 22 receives a signal from the lead motor drive 26 to drive the lead compressor 18, via the lead motor shaft 38, at a desired speed. While several variable speed motors are possible, preferred constructions employ AC variable frequency motors.
The lag compressor assembly includes a lag compressor 46, a lag variable speed motor 50, and a lag motor drive 54. The lag compressor 46 is a rotary screw compressor of the same size as the lead compressor 18 and operates in the same manner as the lead compressor 18. In other constructions the lag compressor 46 may be a different size or type of compressor.
The lag variable speed motor 50 is a variable-frequency motor and operates in a similar way as the lead variable speed motor 22. The lag variable speed motor 50 drives a motor shaft 66 that is coupled to the lag compressor 46 to drive the lag compressor 46. The lag variable speed motor 50 receives a signal from the lag motor drive 54 to drive the lag compressor 46, via the lag motor shaft 66, at a desired speed. While several variable speed motors are possible, preferred constructions employ AC variable frequency motors.
The lag motor drive 54 preferably includes a solid state motor drive that includes a processor and that is connected to the lag variable speed motor 50. The processor receives a signal from the lead motor drive 26 (discussed below) corresponding to a desired operating state (e.g., on or off) that the processor interprets as an instruction to either operate the lag compressor 46 or shut down the lag compressor 46. The lag motor drive 54 receives input power at a fixed voltage and frequency (e.g., 480 volts, 60 Hz) and converts the power to a desired voltage and frequency to drive the lag variable speed motor 50 at a desired speed. The desired speed is determined by the lag motor drive 54 in response to a comparison of the system load 82 and the system output 74. Of course, other lag motor drives such as analog motor drives may be employed if desired.
The holding tank 14 receives the lead compressor output 42 and the lag compressor output 70, defined as a system output 74. A load is connected to the holding tank 14 and consumes or uses the compressed fluid held in the holding tank 14. An output sensor 78 is located upstream of the holding tank 14 and is operable to output a signal representative of the system output 74. A load sensor 86 is located downstream of the holding tank 14 or inside the holding tank 14 and is operable to output a signal representative of a system load 82. It should be noted that while a tank 14 is illustrated herein, other constructions may eliminate the tank or utilize other features such as piping to perform the function of the tank 14. In other constructions, the output sensor 78 may be positioned differently. For example, an output sensor may be located at the output 34 of the lead compressor 18 or at the output 62 of the lag compressor 46 to sense the system output. In yet other constructions, multiple output sensors may be employed. For example, each compressor could include an output sensor positioned adjacent the output to sense the system output. In addition, the output sensor could be positioned anywhere along the discharge line from one or both the lead and lag compressors to the point of use.
In preferred constructions, the lead motor drive 26 is a solid state motor drive that includes a processor and that is connected to the lead variable speed motor 22. The lead motor drive 26 receives a signal from the output sensor 78 corresponding to the system output 74 and a signal from the load sensor 86 corresponding to the system load 82. The lead motor drive 26 compares the system output 74 to the system load 82 and determines a desired speed for the lead variable speed motor 22. The lead motor drive 26 receives input power at a fixed voltage and frequency (e.g., 480 volts, 60 Hz) and converts the power to a desired voltage and frequency to drive the lead variable speed motor 22 at the desired speed.
The lead motor drive 26 also provides a signal to the lag motor drive 54 instructing the lag motor drive 54 to either operate the lag variable speed motor 50 or to allow the lag variable speed motor 50 to idle or shut down. If the system load 82 is less than or equal to the maximum output of the lead compressor 18, the lead motor drive instructs the lag variable speed motor 50 to idle or shut down. If the system load 82 is greater than the maximum output of the lead compressor 18, the lead motor drive 26 instructs the lag variable speed motor 50 to operate. Communication 90 between the lead motor drive 26 and the lag motor drive 54 can be achieved by any reasonable means. For example, the communication 90 may be provided by an electrically conductive wire with a switching mechanism, serial communication, wireless technology, etc. Of course, other lead motor drives such as analog motor drives may be employed if desired.
Although the logic of the lead motor drive 26 is described herein with the use of both a load sensor 86 and an output sensor 78, other constructions may eliminate the output sensor 78 and rely on compressor performance curves.
Operation of the compressor system 10 will now be described in detail with reference to
At operating point A, the lead compressor output 42 and the lag compressor output 70 are both 0%, and the system output is also 0%. Operation of the compressor system at 0% output may refer to an idle state or shut down state of the compressor system 10.
With reference to
As the system load 82 increases over 30%, the system output 74 increases to meet the demand (see
At operating point C, the compressor system 10 transitions into a high load region of operation (Region 2 126 of
As the system output 74 varies between 100% and 200%, the lead compressor output 42 varies between 70% and 100% (30% turn down) while the lag compressor output 70 varies between 30% and 100% (70% turn down).
The compressor system 10 will continue to operate in the high load region of operation, in which the lead motor drive 26 will operate both the lead compressor 18 and the lag compressor 46 to meet the system load 82, until the system load 82 is no longer greater than the lead compressor's maximum output.
At operating point D, the compressor system transitions into a second low load region of operation (Region 3 130 of
Operation in this manner will continue until the system load 82 decreases to a value less than the minimum output of the lead compressor 18, at which point the lead motor drive 26 will instruct the lead variable speed motor 22 to shut down and begin cycling operation, or until the system load 82 increases above 100%. At operating point E, the system output 74 is equal to the minimum output of the lead compressor 18. Because it is assumed that the lead compressor 18 cannot operate below 30%, there is a discontinuity in the graph at operating point E. Again, cycling operation could be employed to provide system output 74 between 0% and 30%.
In general, the low load region of operation may be defined as a region of operation in which the system load 82 may be met by operation of only one compressor (e.g., the lead compressor 18). The lead compressor 18 will operate between a first minimum and a first maximum (e.g., 30% and 100% or with 70% turn down), while the second compressor (e.g., the lag compressor 46) will idle or shut down. When the system load 82 increases to the first compressor's maximum output, the system will transition to a high load region of operation, in which two compressors 18, 46 are required to operate in order to achieve the system load 82. The lag compressor 46 will operate between a second minimum and a second maximum (e.g., 30% and 100% or with 70% turn down), and the lead compressor 18 will operate between a third minimum and the first maximum (e.g., 70% and 100% or 30% turn down). The lead compressor 18 and the lag compressor 46 will operate such that the system output 74 equals the system load 82. When the system load 82 decreases to the maximum output of the lead compressor 18, the compressor system 10 will transition to a second low load region of operation, in which only the lead compressor 18 operates to meet the system load 82. The minimum speed of the lead compressor 18 will be adjusted such that the lead compressor 18 will again operate between the first minimum and the second minimum (e.g., 30% and 100% or with 70% turn down). The lag compressor 46 will again idle, or operate at 0%.
The logic of the lead motor drive 26 may also operate the system in a slightly different manner by modifying its definitions of the regions of operation. For example, the compressor system 10 may operate in the low load region of operation when the system load is less than 90%, rather than 100%. In this situation, the operating points corresponding to the transition points on the graph will shift to reflect the changes in the operating regions.
With reference to
The lead motor drive 146 will receive a signal corresponding to the system output 214 from an output sensor 218 and a signal corresponding to the system load 226 from a load sensor 230. The lead motor drive 146 will compare the system output 214 to the system load 226 and determine a desired speed for the lead variable speed motor 142 and determine the desired operating states for each of the lag variable speed motors 166, 190.
The lag motor drives 170, 194 each communicate with the lead motor drive 146 to receive a signal corresponding to a desired operating state that the lag motor drives 170, 194 interpret as an instruction to either operate the lag compressor 162, 186 or to shut down the lag compressor 162, 186. The lag motor drives 170, 194 determine a desired speed of each lag compressor 162, 186, respectively. The lag motor drives 170, 194 will send a signal to the lag variable speed motors 166, 190 to drive the lag compressors 162, 186 at the desired speeds determined by the lag motor drives 170, 194 in response to a comparison of the system load 226 and the system output 214.
The compressor system 134 is operable in a low load region of operation, an intermediate load region of operation, and a high load region of operation. The low load region of operation may be defined as a region of operation in which the system load 226 is less than 100%, in which only operation of the lead compressor 138 is required to meet the system load 226. The intermediate region of operation may be defined as a region of operation in which the system load 226 is greater than 100% and less than or equal to 200%, in which operation of two compressors (e.g., the lead compressor 138 and the first lag compressor 162) is required to meet the system load 226. Finally, the high load region of operation may be defined as a region of operation in which the system load 226 is greater than 200% and less than or equal to 300%, in which operation of three compressors (e.g., the lead compressor 138, the first lag compressor 162, and the second lag compressor 186) is required to meet the system load 226. The operation of the compressors 138, 162, 186 and the transition between each region of operation is similar to the example described above.
The lead motor drive 146 typically operates the compressor system 134 with the least number of compressors. In this way, the lead motor drive 146 uses the compressor system 134 most efficiently. However, in some constructions, it may be more efficient to not operate with the absolute minimum number of compressors. For example, it may be determined to be more efficient to operate the compressor system 134 such that it transitions between regions of operation when the compressors operate within 10% of their maximum outputs. The most efficient operation would be determined and preprogrammed into the logic of the lead motor drive 146 during the design of the compressor system 134.
Thus, the invention provides, among other things, a compressor system that operates a plurality of compressors without the use of a system controller. Various features and advantages of the invention are set forth in the following claims.
Roberge, Jason A., Mehaffey, James D., Bender, Frederick E.
Patent | Priority | Assignee | Title |
10528024, | Jun 17 2013 | Self-learning production systems with good and/or bad part variables inspection feedback | |
10590937, | Apr 12 2016 | Toyota Motor Engineering & Manufacturing North America, Inc. | Compressed air system and method of operating same |
11018610, | Jan 27 2017 | FRANKLIN ELECTRIC CO , INC | Motor drive system and method |
11349419, | Jan 27 2017 | Franklin Electric Co., Inc. | Motor drive system including removable bypass circuit and/or cooling features |
Patent | Priority | Assignee | Title |
4102149, | Apr 22 1977 | BANK OF NOVA SCOTIA, THE | Variable capacity multiple compressor refrigeration system |
4259038, | Dec 21 1977 | DANFOSS A S | Method and regulator for controlling the delivery of a pump arrangement according to demand |
4526513, | Jul 18 1980 | BRISTOL BABCOCK INC | Method and apparatus for control of pipeline compressors |
4560319, | Aug 01 1983 | MAN MASCHINENFABRIK UNTERNEHMENSBEREICH GHH A CORP OF GERMANY | Method and apparatus for controlling at least two parallel-connected turbocompressors |
4646530, | Jul 02 1986 | Carrier Corporation | Automatic anti-surge control for dual centrifugal compressor system |
5522707, | Nov 16 1994 | METROPOLITAN INDUSTRIES, INC | Variable frequency drive system for fluid delivery system |
6185946, | May 07 1999 | Optimum Energy, LLC | System for sequencing chillers in a loop cooling plant and other systems that employ all variable-speed units |
7240502, | Nov 04 2003 | LG Electronics Inc. | Method for controlling operation of air-conditioner |
20050244277, | |||
20060225445, | |||
20070107449, | |||
20070227167, | |||
RE29621, | Oct 14 1976 | Snyder General Corporation | Variable capacity multiple compressor refrigeration system |
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